Functional ontology machine-based narrative interpreter

ABSTRACT

A system and method for analyzing narrative data based on a functional ontology using semiotic square functions to produce analyzed data outputs. A computer implemented method accesses narrative data and reads a semiotic square function data table for each verb in the sequence of words, each semiotic square function data table classifies at least one verb in each sentence pattern as a functional type and includes one or more words in a semiotic square relationship to the verb classified, the functional type applying at least one symmetrical relationship between a first actor and a second actor in the narrative data. The method parses each sentence which includes a verb matching a functional type to match sentence subjects and objects to an event template and outputs an analysis of the narrative data relative to a common story theme based on a sequence of event records.

PRIORITY CLAIMS/RELATED APPLICATIONS

This patent application claims priority under 35 USC 120 and is acontinuation of U.S. patent application Ser. No. 15/081,590, filed Mar.25, 2016 and entitled “Functional Ontology Machine Based NarrativeInterpreter”, the entirety of which is incorporated herein by reference.

BACKGROUND

Narratives may comprise written accounts of connected events. A storymay include a narrative, actors or characters, and descriptive elements.Written stories are a primary way that many people consume news andentertainment. Many stories have a dynamic quality in that the story maychange over time. News stories are updated as new related events occur,requiring news providers to gather new information, generate new text,and update any previous version of the story or author a completely newstory.

Many people consume news stories in electronic form on various types ofuser devices. There is therefore a large availability of electronicnarrative data which can be processed by computing devices. Because ofthe large amount of information available via public and privatenetworks in electronic form, processing such data becomes increasinglydifficult.

Linguistic computing presents a number of challenges in terms ofdefining relationships between complex story events.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A depicts a generic semiotic square structure utilized inaccordance with the present technology.

FIG. 1B depicts an exemplary semiotic square utilized in the technologydiscussed herein.

FIG. 2 is a computing system environment suitable for implementing thetechnology for narrative interpretation discussed herein.

FIG. 3 is a flowchart illustrating a general computer implemented methodfor analyzing a narrative in accordance with the technology discussedherein.

FIG. 4 is a flowchart illustrating a step of building an events table inthe method of FIG. 3.

FIG. 5 is a flowchart illustrating a step of interpreting events in theevent table.

FIG. 6 is a flowchart illustrating a step of mapping events to anarrative.

FIG. 7 illustrates a first type of analysis which may be performed onnarrative data which includes building a timeline of events for a story.

FIG. 8 illustrates a second type of analysis which may be performed onnarrative data comprising predicting a next event in the story.

FIG. 9 illustrates a second type of analysis which may be performed onnarrative data comprising detecting similarities between the narrativeand other narratives.

FIG. 10 is a flowchart illustrating a computer in the process forimplementing a semiotic square substitution for components of cases,events and stories, which may be utilized in any of the analysesdiscussed herein.

FIG. 11 is a table illustrating a semiotic square reflected in datastructure for a series of abstract transfer functions.

FIG. 12 is a table illustrating a semiotic square reflected in datastructure for a series of mental transfer functions.

FIG. 13 is a table illustrating a semiotic square reflected in datastructure for a series of emotional transfer functions.

FIG. 14 is a table illustrating a semiotic square reflected in datastructure for a series of physical transfer functions.

FIG. 15 is a table illustrating a semiotic square reflected in datastructure for a series of conflict transfer functions.

FIG. 16 is a table illustrating a semiotic square reflected in datastructure for a series of abstract transactions.

FIG. 17 is a table illustrating semiotic square reflected in datastructure for a series of mental transactions.

FIG. 18 is a table illustrating a semiotic square reflected in datastructure for a series of conflict transactions.

FIG. 19 is an illustration of a sentiment taxonomy.

FIG. 20 is an illustration of a narrative balance for an actor in anarrative.

FIG. 21 is an illustration of a semiotic square of an axiologicalontology.

FIG. 22 an illustration of a narrative taxonomy utilized classifystories into particular narrative genres.

FIG. 23 is an illustration of a characters or actors taxonomy utilizedto characterize actors within a particular story.

FIG. 24 is an illustration of a computing system environment suitablefor moving a story-based social network. In accordance with the presenttechnology.

FIG. 25A illustrates a computer generated summary of a televisionprogram with emphasis on a sentence whose structure is exemplified inthe data structures shown herein.

FIG. 25B illustrates a data structure encapsulating the summary of FIG.25A.

FIG. 26 illustrates a first portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 25A.

FIG. 27 illustrates a second portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 25A.

FIG. 28 illustrates the data structure of FIG. 25B used to store adifferent sentence and different summary.

FIG. 29 illustrates a first portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 28.

FIG. 30 illustrates a second portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 28.

FIG. 31 illustrates a data structure referencing event data structuresand which may be used in the creation of a time line.

FIG. 32 illustrates a partial data structure storing an event time linefor a given character protagonist in a story.

FIG. 33 illustrates a data structure storing the ontology of the presenttechnology to characterize a protagonist.

FIG. 34 illustrates a partial data structure storing a frequencybreakdown of a story for use in clustering prediction.

FIG. 35 illustrates a partial data structure storing a frequencyanalysis for clustering prediction in accordance with the presentsubject matter.

FIG. 36 is an illustration of an exemplary computing system suitable forimplementing in the computing systems discussed herein.

DETAILED DESCRIPTION OF ONE OR MORE EMBODIMENTS

The technology, briefly described, comprises a system and method foranalyzing narrative data based on a functional ontology using semioticsquare functions to produce analyzed data outputs. Various types ofanalysis are provided. The technology takes the form of a computerimplemented method, a computing system and/or code configured toinstruct a computing system to perform a plurality of computing steps toproduce an analysis of input narrative data. The technology may includea computer implemented method which accesses narrative data, thenarrative data comprising a sequence of words arranged in sentencepatterns. The method reads a semiotic square function data table foreach verb in the sequence of words, each semiotic square function datatable classifies at least one verb in each sentence pattern as afunctional type and includes one or more words in a semiotic squarerelationship to the verb classified, the functional type applying atleast one symmetrical relationship between a first actor and a secondactor in the narrative data. The method parses each sentence whichincludes a verb matching a functional type to match sentence subjectsand objects to an event template and stores data from each subject andobject in a sentence as an event record. The method outputs an analysisof the narrative data relative to a common story theme based on asequence of event records. The analysis may be a timeline of events, aprediction of next events and/or a comparison of similarity to otherstories.

This Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used as an aid in determining the scope of the claimed subjectmatter.

The technology discussed herein comprises a system and methods foranalyzing narratives provided in electronic narrative data formutilizing a processing system. The technology uses patterns in theelectronic narrative data and data structures incorporating data definedusing semiotic squares to analyze the narrative data to analyze storiesand elements of textual content, find similarities amongst variousstories, predict events which may occur in the stories, and providevarious types of analysis on the narrative data in a programmaticmatter.

The technology herein decomposes each set of narrative data into aseries of discrete events, each event having a specific data structureand elements, and maps the events onto stories. Events are created basedon a semiotic ontology, which defines verbs in sentences as of a numberof different functional types. Based on the defined functional ontology,sentences are broken down into cases and events. Events can then beutilized to provide the different types of analyses, including creatinga timeline, making a prediction about the next event in the story, andfinding similarities between in individual story and other stories basedon their semiotic structures.

The technology herein is based on semiotic squares at multiple differentlevels. At a first level, the squares are used to analyze the ontologyof transaction-based functional verbs. A data structure comprising aplurality of verbs utilized in a particular language includes the rootform for the semiotic square, and any number of verbs which complete oneor more semiotic squares for that particular form. This semiotic datastructure can be utilized at various levels in the analysis. At anotherlevel, the system looks for patterns which can be used to analyzestories. At yet another level, substitutions from a semiotic square intovarious events are utilized to detect similarities and semioticstructures across various stories.

FIG. 1A illustrates a semiotic square, a tool used in structuralanalysis of the relationships between semiotic signs through theopposition of concepts. A semiotic square model can be used by thepresent technology to provide a narrative analysis in accordance withthe discussion herein. The semiotic square model illustrates a number ofrelationships between functions in a narrative. A first relationship isbased on a diagonal contradiction which is the presence/absence of aparticular property such as Intelligence, Wealth, Appetite, Power,Beauty, Honesty, etc. As shown in FIG. 1A, 2 pairs of diagonalcontradictions are obtained: A/Non-A, and B/Non-B. The secondrelationship is an opposition or antagonism of aims. For example, ifappetite is aimed at eating, then anorexia is aimed at fasting. This isnot a privative relationship, as anorexia is not defined by an absenceof appetite, but instead by a willingness to not eat. In FIG. 1A, therelationship A/Non-A is the contradiction between do and don't do andA/B is the opposition between do and do not. Far from being privative,the will is equipollent, but the outcome is oriented in an oppositedirection. In the semiotic square model of FIG. 1A, “A” is the A-nesswhich is the full realization of the property, the no nonsense summit,the factual one and “Non-A” is the failure, the absence, the un-A. “B”is the de-A, where A is deconstructed; this is a darker summit, whererenouncement goes with deceit (renouncement to trust) or denial(renouncement to assertion). Finally, “Non-B” is the privation of thisnegative orientation, turning the same energy into an additiverelationship.

SPA represents nominal, positive action. A subject's energy is orientedtowards the achievement of a goal. SPNA is the nominal, failure toachieve the action which is supposed to be initiated by its subject. Thefailure is realized in absentia and may be reflected as a lack or lossof resources, skills, or energy. SPB represents energetic, emotional,negative counter action (antagonism) relative to SPA, oriented againstthe action which is supposed to be initiated by its subject, or towardsthe achievement of the failure thereof. The counteraction is realized inpraesentia: sabotage, boycott.

SPNB represents an energetic, emotional, or positive action. Thesubject's energy is oriented towards an unrestricted, self-indulgingachievement of the goal.

Note that SPA or “positive” action refers to the expected result, andmight have a negative or regressive formulation. Likewise, the SPB orantagonism can have a positive flavor. For example, one semiotic squaremay be reflected as: SPA—damage control; SPNA—out of control;SPB—proliferation; and SPNB—elimination.

Deixis are fundamental dimensions of the semiotic square. There is one“positive” deixis, and one “negative” deixis. The deixis is a posture“for and “against” to emphasize that the two “sides” of the basicsemiotic square are exclusive and potentially argumentative. The deixisis not only a certain value and a certain orientation, it is also astatement which may be supportive or adverse. The deixis height isdescribed by its orientation, and is modulated by its intensity.

FIG. 1B represents a specific example of a semiotic square used in thepresent technology. In the present technology, the heuristic value ofthe square may be applied to elements of stories and story rulesutilized by the technology to output various analyses of input narrativedata describing a story.

The technology utilizes an application of the semiotic square to variousnarratives. The technology herein is based on the premise thatcommunication is consubstantial to narratives, and using the corelexical semantics of a semiotic square results in a micro narrative foreach term defined as the root of the semiotic square (SPA).

The semiotic square model allows core lexical semantics to be appliedconsistently the full vocabulary of the English language (or any otherlanguage). In FIG. 1B, the first relationship in a semiotic square isbased on the opposition between assertion and absence, which isasymmetrical. If “eat” is asserted, then “fast” is to abstain from food(absence of appetite or absence of the right to eat). The secondrelationship is based on the adversity to what was asserted. If “eat” isasserted, denial of hunger is the adverse energy behind anorexia. Thethird relationship is based on the refusal of adversity, which ends upas a zealous support of assertion i.e. refraining from eating. Thefourth relationship explains absence, as a repulsion of excess. Theserelationships provide the pervasive values behind the semiotic squaremodel: starting from the matter of fact, and rotating clockwise, one hascynicism (adverse), asceticism (privative), and enthusiasm (excessive).This core ontology stands throughout the entirety of the Englishlexicon.

The two deixis, positive and negative, are symmetrical. The left(positive) deixis is generally based on a presupposition of states andgradation of intensity: excess directly presupposes assertion, and is amore intense state of the same. The negative deixis reflects a denial,and presupposes absence, and anorexia diet. Both deixis though are firstand foremost defined by their argumentative stake: anorexia is moreexactly defined as an inverted gluttony than as an excessive diet, andthe reverse is true for anorexia vs. gluttony.

A swap of these two positions is a staple of plot reversals. Forexample, some stories reflect that a most hardened criminal can beconverted into a good person. The principles are used in analysis ofnarrative data relative to stories in the present technology.

FIG. 2 illustrates the functional components of a computing environment200 suitable for use with the present technology. The environment 200includes hardware (as illustrated in FIG. 37) which may include one ormore processors, nonvolatile memory, and random access memory suitablefor implementing the functional elements and storage elements. Computingenvironment 200 includes a parser 205, an event interpreter 212, and ananalysis engine 250 which includes a story interpreter 214. Also shownin computing environment 200 are a parser dictionary data store 215, asentence rule data store 220, event rule data store 230, story rule datastore 240, semiotic square and function mapping data store 245 and aclassified/mapped data store 280. Computing environment 200 takes asinput electronic narrative data 218 in textual form for evaluation.Multiple items of narrative data 218 may be used as input for a singlestory or multiple stores. The parser 205 breaks down elements of thenarrative data for use by other processing elements. The eventinterpreter takes parsed data from the parser and maps parsed data intoevents based on event rules 230 and semiotic square and function mappingvalues from the semiotic square and function mapping data store 245.Events can be store in the classified/mapped data store 280, andprocessed by the analysis engine 250. One component of the analysisengine 2250 is the story interpreter which may generate collatedstories, timelines and other types of outputs which are provided to anoutput device 260. A classified/mapped data store 280 stores multiplelevels of evaluated text from input narrative data 218, including parseddata identified as parts of speech, verbs classified by their functionalmapping, mapped event data, mapped case data, and mapped story data. InFIG. 2, while the parser 205, event interpreter 212, story interpreter214, an analysis engine 250 are depicted as separate functionalelements, it will be recognized that these functional elements may becombined in any number of different combinations and need not comprisephysically or programmatically separate elements. Furthermore while eachof the respective data structures are illustrated as separate datastructures, the organization illustrated in FIG. 2 is for convenience inunderstanding only. The specific data structures utilized can becombined and organized in other logical ways.

Narrative data 218 may comprise data input from various sources such ascommercial new sources, user data, social networks, or any third partynarrative textual data source. Multiple sets of data may be provided asa set of data. Narrative data may comprise a story drafted on a givendate at a given time.

Each story comprises a narrative and cast, where each narrative is apattern of events. Multiple stories based on multiple items of narrativedata 218 may be analyzed, each story analysis building on any previousstory analysis performed by computing environment 200. Various versionsof a single story theme or subject may be provided.

Analyses performed by the computer environment 200 are provided to anoutput 260. The output 260 may comprise, in various environments, anyform of user perceptible device including, but not limited to, a displaydevice, another computing environment, a processing device, or aprocessing service, such as a story-based social network as describedherein.

Parser 205 is configured to accept each of any number of sets ofnarrative data 218, reduce each of the words therein into individualtokens and parts of speech, and present the tokens parts of speech (POS)to the interpreter 212. Parser 205 is configured to evaluate Englishgrammar patterns for phrases, clauses, and sentences, data for which hisstored in a parser dictionary 215. A sentence pattern is a sequencecombining clause patterns, phrase patterns, and parts of speech. Theparser 205 breaks down sentence patterns to extract and classify partsof speech in incoming text in the narrative data 218.

Sentence rules 220 provide grammar patterns for phrases, clauses, andsentences, and are utilized by the parser 205 to break down the textnarrative data 218 into usable data structures allowing computation andanalysis as discussed herein.

The event interpreter 212 utilizes event rules 230, and semiotic squarevalues and function maps data store 245 to classify functions and partsof speech into case structures (or frames), and later into eventstructures, which can then be mapped to story patterns.

The functions performed by the parser 205, event interpreter 212 andstory interpreter 214 may be integrated into one or more softwarecomponents run on a processing device similar to that illustrated inFIG. 37, provided as separate components, separated into differentprocessing environments and different processing devices, and run inserial or in parallel processing environments.

The analysis engine 250 may perform various types of analyses on thedata classified as events by the event interpreter. In one example, thestory interpreter 214 orders a textual sequence from the narrative data218 into a set of threads inside a story, sometimes referred to hereinas a timeline.

Once one or more sets of narrative data 218 have been broken intodiscrete events by the event interpreter 212, each event may be storedas event data in the classified and mapped data store 280. The storyinterpreter 214 reads the classified and mapped data store 280 for eventdata to be mapped to stories. Events can be further processed by theanalysis engine 250. Once the narrative data is broken into events, onecan perform any number of different manipulations of the events,including but not limited to the creation of timelines, creatingdynamically updating timelines (as new events occur), and predictingfuture events in timelines or stories.

Different types of analyses are provided by the analysis engine 250. Inone type of analysis, analysis engine 250 can provide a timeline ofdiscrete events, defined in terms of a number of events and theimportance of the events. Still further, the analysis engine 250 cangenerate predictions using a prediction engine. A prediction of a nextpossible event in a story can be created using the techniques discussedherein. In addition, a similarity determination can be made betweenstories. For example, a current news story regarding the potentialcheating of a sports organization's marquee quarterback can be comparedand found similar to cheating scandals involving marquee players inother sports, or cheating scandals involving the same organization butinvolving different personnel.

FIG. 3 illustrates a method performed in accordance with the presenttechnology to provide machine implemented story analysis. At 305, at anytime prior to receipt of narrative data for story analysis, an analysisfunctional ontology is created. The ontology is utilized as a foundationfor the analysis provided herein to both extract and characterize eventsin input narrative data and to map those events to a story. The examplesof such characterization will be presented herein as example in English,but it should be understood that the underlying principles herein willapply to any language. In the present technology, verbs are classifiedinto an ontology based on their functions. In alternative embodiments,the ontology may be continuously updated at 305 as processing of newsets of narrative data continues.

Once the ontology is created at 305, at 307 for each set of narrativedata 218, narrative data source text is retrieved at 310, and parsed at320 to find tokens (verbs) and identify parts of speech. The tokens andparts of speech are utilized to build case frames at 350 which arestored as element records (FIG. 26-27). These case frames are thenmapped to event frames at 360. Both case frames and events are stores asdata structures, mapping the text from the narrative data source to datastructures which can be utilized programmatically to produce an outputof the analysis engine. Examples of such data structures are shown inFIGS. 26-30. Once events are mapped and stored in event frames, theresult of step 360 is a plurality of event records for each item or setof narrative data. The event records may be manipulated in a variety ofways. In one embodiment, events are mapped to a narrative context by thestory interpreter, and can be manipulated to produce one of severaltypes of story analyses as indicated at 370 in FIG. 3. Events are thenmapped to timelines or other analyses for output at 370.

The method moves on to the next input data source 380. At 390, based onthe events table, functional mapping and narrative mapping, an analysisof the story can be prepared. Various examples of story analysis aredescribed herein. Each of these various steps as described furtherbelow.

With reference to step 305, in one embodiment, the method classifieswords into an ontology including functions (verbs), actors (nouns) andshades (adjectives/adverbs). Each classification in this ontologydescribes an importance to various types of functions, actors, andshades. In accordance with the technology, a unique structure ofproperty isotopies (physical, cognitive, and the like) is used toorganize both entities and transformations, based on a functionalmapping between transformations and properties.

For each classified word in the ontology, semiotic squares may be built.As used herein, a semiotic square for a word is provided in a datastructure identifying for each root word those words related in asemiotic square. Some squares include all four terms of the square (SPA,SPB, SPNA, SPNB) while others may have only partial terms. Building asemiotic square for each word comprises creating a data structureincluding, for each word, between one and three additional termscompleting the square. While conventional formalisms have languageformalized as a first-order predicate logic in terms of dyadic antonyms,the semiotic square model adds two values to the dyadic antonyms and itadds a deictic perspective to the self-stated and context-free value ofthe initial pair.

Choices as to elements for each of the values of any square are definedin the semiotic square data store 245. In one example, data structuressuch as those illustrated in FIGS. 11-18 (showing representativeportions of data structures for various functional classifications) areused. Definition of each square is created in the data structure priorto use of the data structure in analysis. In one embodiment, such datastructures are stored in the data store 245 of FIG. 1. As a result, datastore 245 may include thousands of defined semiotic squares.

In further consideration of step 305, ones of the squares defining verbsinto various functional classifications are used interpretively. Inaccordance with the semiotic ontology, each verb in the language isclassified into one of a number of functional types. Such functionaltypes are classified as DO, and MAKE or TRANS. TRANS functions comprisethree different types: TRANS-formation, TRANS-action, and TRANS-ferfunctions.

DO functions comprise all verbs that do not alter the state of arecipient (or actor), or do not involve an agent when they have arecipient (or actor).

A first type of DO verbs are the “state” and “activity”, “atelic”, verbsas defined in Vendler, Zeno (1957). “Verbs and times”. The PhilosophicalReview 66 (2): 143-160. Under Vendler's model, events may be classifiedinto one of four aspectual classes: states, which are static and do nothave an endpoint (“know,” “love”); activities, which are dynamic and donot have an endpoint (“run,” “drive”); accomplishments, which have anendpoint and are incremental or gradual (“paint a picture,” “build ahouse”); and achievements, which have an endpoint and occurinstantaneously.

A second type DO verbs describe natural or physical changes: erupt,blossom, effervesce, etc. Although this second group of verbs generallydo not have actors or agents, it is possible to consider semiotic squarepatterns for each of these type of verbs. For example, “flow” is a stateof a liquid. A semiotic square for “flow” may be SPA: “Flow,” SPB:“Obstruct,” SPNA: “Trickle,” SPNB: “Pour.” Note that DO verbs can havean instrument or object, for example “Walk with a stick.”

All other verbs fall into the TRANS category comprising:TRANS-formation, TRANS-fer and TRANS-action. Each such verb has an actor(person) who is an agent. TRANSFERS and TRANSACTION have an animatedrecipient actor, and are typically ditransitive. Examples include:accord, afford, allocate, allow, and appoint. Each of these examples isa verb which takes a subject and two objects which refer to a theme anda recipient. These objects may be called direct and indirect, or primaryand secondary.

Each type of function in the ontology allows for basic assumptions aboutthe use of the verb to be utilized in computational narrative analysis.

TRANSFORMATIONS generally refer to a function of “to MAKE” and aretherefore classified by the system as “MAKE” functions in a datastructure mapping the terms to parts of speech. TRANSFORMATIONS areverbs of the form taken by objects, including their properties, andtheir formation (or changes to their state). A TRANSFORMATION is afunction applied to a recipient to change its property from one state ofproperty or intensity to another. The resulting state entails thepre-supposed pre-existing state, since MAKE changes the direction of aproperty to its opposite value.

A TRANSFORMATION function verb does not have both a donor and recipientwhich are animated. As such, either a sentence subject or a sentenceobject may be animated, but not both.

In a TRANSFORMATION clause, if the object OAexample, the statement“Cancer killed him” maps subject, verb and object as follows:S=‘cancer’, V=‘killed’, O=‘him’. Since ‘cancer’ is inanimate, it becomesan instrument of the transformation verb “killed” such that a mapping ofthe sentence by the parser (discussed below) may be {MAKE, objectO=‘him’, ‘PHYSICAL_STATE’, ‘dead’ is the SPNA, the instrument INST,‘cancer’}.

Conversely, if the subject S is animated, the object 0 is not, thisreflects a passive object and the subject becomes the instrument.Consider the exemplary sentence: “He died from cancer.” If there is aninstrument (‘from cancer’), then there is a change of state. Since ‘he’doesn't control the action, the object slot shifts such that a mappingof the sentence by the parser may be object O=‘he’, ‘PHYSICAL_STATE’,‘dead’ is the SPNA, and the instrument INST, ‘cancer.’ This mapping maytake the form {MAKE, O=‘he’, (‘PHYSICAL_STATE’, ‘dead’, SPNA), INST,‘cancer’}.

This is in contrast to a sentence such as “Somebody killed him.” Asdiscussed below, where S and O are animated entities, this is a contractand the function is a TRANSFER function. A mapping of a transferfunction may take the form {XTRANSFER, S=‘somebody’, 0=‘him’, (‘ATTACK’,SPNA)}. (An XTRANSFER function is a type of TRANSFER function, discussedbelow.)

Another type of TRANS verb is a TRANS-fer which deals with verbs thattransfer an object without direct reciprocity between actors, as in“send” or “receive.” In a TRANSFER function, a contract between twoactors is implicit (and required), and breaking the contract is atransgression.

TRANSFER verbs can be separated into abstract transfer (ATRANS), mentaltransfer (MTRANS), emotional transfer (ETRANS), physical transfer(PTRANS) and conflict transfer (XTRANSFER).

Abstract transfer functions comprise verbs denoting transfer ofpossession. Example verbs of this type include “get,” “give,” and“donate.” An exemplary semiotic square for “give” would be:SPA—“give/receive,” SPNA—“not give or not receive,” SPB—“deprive,” andSPNB—“spoil.”

FIG. 11 illustrates a semiotic square data table for a series ofabstract transfer (ATRANS) functions. The table may be stored in a datastructure such as data store 245 of FIG. 1. The table 1100 in FIG. 11 ismerely representative of a small portion of the data which structure1100 may be included in the computing environment 200. It will beunderstood that there are thousands of more rows than those illustratedin FIG. 11, but for simplicity only a subset of the rows in the datastructure are shown.

For a given term “give” in FIG. 11, each row illustrates a square 1110of the term, with subsequent rows in any same column comprising synonymsat their relative place in the data structure. For the term “give” inthe ATRANSFER (SPA) column, SPB is “keep”, SPNA is “deprive”, and SPNBis “gratify”. The terms “sell”, “buy”, and “obtain” are all synonyms of“give,” with “steal” being the opposite of “obtain.”

Mental transfer functions (MTRANS) comprise those functions denotingcommunication, or a mental or spiritual transaction. Examples of mentaltransfer functions include transfers of knowledge: “educate”,“convince”, “influence”. Examples further semiotic squares for “advise”or “listen” (as SPA) would include “not suggest” or “not listen”, “freemind”, and “exhortation.” FIG. 12 is a table illustrating a semioticsquare data table for a series of mental transfer functions. Again, FIG.12 represents only a small portion of the data store 245 of computingenvironment 200.

Physical transfer functions (PTRANS) are verbs denoting a travel orphysical movement. FIG. 14 is a table illustrating a semiotic squaredata table for a series of physical transfer functions.

Emotional transfer functions (ETRANS) are verbs denoting a transfer ofan emotional state. Examples include “like” and “love”. FIG. 13 is atable illustrating a semiotic square data table for a series ofemotional transfer functions.

The conflict group of transfer verbs (XTRANSFER) is often found innarratives, associated with typical actors: villain, victim, nemesis,ally, traitor, under cover, mediator, and witness. These functions alsohave typical and predictable prequels and sequels: transgress, attack,ask for/get help, retaliate, pursuit, retribution; and predictablesequences of events: attack, mediate, witness, retaliate, pursuit,retribution. Conflict transactions can include a twist: witness becomesvictim, or a party is betrayed. FIG. 15 is a table illustrating asemiotic square data table for a series of conflict transfer functions.

Another functional type are TRANS-actions. TRANSACTION functions havedonor, recipient, and object. The actors or parties involved aregenerally more important than the object involved, and the object of thetransaction is likely to stay unchanged other than the change in theownership.

Most transactions are expressed by entailment: something that followslogically from or is implied by something else. For example: “If youtake a drug, this drug has been administered to you.”

TRANSACTION functions can likewise be broken down into abstract(ATRANSACT) transaction functions, mental (MTRANSACT) transactionfunctions and conflict (XTRANSACT) transaction functions. FIG. 16 is atable illustrating a semiotic square data table for a series of abstracttransactions. FIG. 17 is a table illustrating semiotic square data tablefor a series of mental transactions. FIG. 18 is a table illustrating asemiotic square data table for a series of conflict transactions. Again,each of FIGS. 16, 17 and 18 are only partial representations of datatables utilized to store classifications of the functional ontologydescribed herein.

Included in the ontology are sentiments, emotions and sensations,collectively referred to herein as “shades.” Shades are generallyintroduced by adjectives and adverbs. FIG. 19 is an illustration of asentiment or shade taxonomy.

Adjectives used to express properties, and verbs used to express changesoccurring to these properties, are generally equivalent. Intransformation verb uses, the nuances of time or accomplishment in thedifferent ways of expressing the change of state are generallyirrelevant. The differences between these phrases “I'm angry” relativeto the phrase “This angers me” are insubstantial from a story analysisperspective.

The ontology used in the present technology defines what can beconsidered to be a set of micro-narratives. As opposed to pairs ofopposing words, the semiotic square lexicon includes, the basis of amicro-narrative based on a presumption of narrative balance. Thenarrative balance foundation states that, for almost any story, a“balance” exists between positive and negative elements or actions inthe story. Consider for example a simple story where a villain startsout with a good degree of power and ultimately ends up being the subjectof justice. Actions of the villain at the beginning of the story lead torepercussions for such actions at the end of the story.

The functional ontology—the classification of the verbs intofunctions—carries through the programmatic analysis of narrative data byallowing programmatic coupling of relationships in events to expandanalysis of narrative data into various different types of outputs.

Each semiotic square may have a similar built in balance. Consider thesquare of “Flow,” “Obstruct,” “Trickle,” “Pour.” Where there is anobstruction, “flow” is prevented, but one may consider that at somepoint the obstruction will be removed and the flow restarted. Theinherent balance in each semiotic square may be utilized in conjunctionwith the ontology as the basis for elements of the predictive analysissystem herein.

This narrative balance is built into the constructs, described herein,which are utilized in the computations of story analysis.

Returning to FIG. 3, as a set of narrative data text is received at 310,the set of data is parsed at 320 to find tokens and parts of speech.

Finding inputs for event analysis is performed by the parser 205. Theparser may comprise code adapted to evaluate English grammar patternsfor phrases, clauses, and sentences. A sentence pattern is a sequencecombining clause patterns, phrase patterns, and parts of speech. Theinterpreter breaks down sentence patterns to extract and classify partsof speech in incoming narrative data.

An exemplary sentence pattern is “c contrast_connective c” where “c” isa clause and “contrast_connective” is a connector between the clauses.Taking as an example the sentence “This hurts but I don't mind”, thesentence maps to: c: “this hurts”, contrast_connective: “but”, c: “Idon't mind”. Note that sentence patterns are discourse patterns usingconcession, contrast, and the like. These connective patterns arecarried along to other portions of the text evaluation to help theparser 205 to articulate the thread in a sentence of data.

A clause pattern breaks down into a noun part (np) and a verb part (vp)(clause pattern=np vp). For example “This sucks” maps to {np: “this”,vp: “sucks”} and “I don't mind” maps to {np: “I”, vp: “don't mind”}.This mapping may be stored in the mapped and classified data store 280.

The clause pattern may be further broken down into a phrase pattern of aproper noun (pn). The phrase pattern may simple be the nouns, where, forexample, “this” maps to {pn: “this”} and “I” maps to {pn: “I”}.

Each level of pattern (sentence, clause, phrase) is evaluated using aset of rules describing each possible pattern at that level Exemplarysentence rules may take the form:

(s, [c]),

(s, [c, break?, contrast_connective, c]),

(s, [contrast_connective, c, break?, c])

The above sentence rules show three examples of a set of sentence ruleswhich may run into the thousands. Clause rules take the form:

(c, [vp, pp?]), (c, [aux, np])

Similarly, while only one clause rule is illustrated above, clause rulescan run into the thousands for various presentations of clausesavailable in the English language. In the above clause rule example, thequestion mark allows the parser to skip optional items. “Soft” breaksmay close a clause, although they can be explicitly stated as mandatoryor optional.

An exemplary phrase rule takes the form:

(np, [det, adj, n]), (np, [pn]

Again, there may be hundreds or thousands of phrase rules defined foreach computing environment 200. Sentence rules are stored in a sentencerules data store 220, while clause and phrase rules may be stored in theparser dictionary data store 215. It should be recognized that thesedatabases can be combined.

The parser 205 will match the word values to a parser dictionary datastore 215 which includes a definition for each word, the definitionclassifying the word as its potential usage form in sentences. Suchlists can be updated dynamically as needed as meanings of words changeover time.

The result of the parsing performed at 320 is a set of tokens and partsof speech which are used by interpreter 212 to classify the mapped datain data store 280.

Returning to FIG. 3, at 350, events analysis occurs by mapping thephrases and clauses to a case frame, with each case frame based on thefunctional classification. The events are stored by EVENTID in theclassified/mapped data store 280 at 360. A method for mapping verbs andparts of speech to a case frame which is later used for event analysisis discussed below with respect to FIG. 4.

FIG. 4 illustrates one method for performing step 350 in FIG. 2. At 405,for each token and part of speech combination, then at 410, method willattempt to map the token and part of speech combination to a particularcase frame. A token comprises a functional verb defined in accordancewith the foregoing description.

A case frame is a mapping of the token and part of speech into one ormore context maps. Each case frame is a map of the sentence data to asubject, an object, circumstances (i.e. time, location, instrument),shades (manner and tone), and an excerpt. Each mapped case frame maycomprise a case frame record identifying the respective words in asentence to their constituent portion of the case frame.

The event interpreter loops though steps 410, 420, 425 and 450 toattempt matching of tokens and parts of speech combinations to caseframe patterns. At 410, pattern items are demonstrated from left toright in a sentence of text data, following case frame rules and using asyntactic unification of first-order terms. The unified terms of thefirst successful solution are returned as the dictionary of bindingresults (unifiers in solution) at 420 and the case frame is selected at460 and stored at 470.

Additional rules map the interpreter bindings to the case frame at 460,where each case frame may include: SUBJECT (agent), FUNCTION, OBJECT,and RECIPIENT at 460. Additional rules include, for a subject:

-   -   If the voice is active, and there is no inversion, then the lead        noun in the lead np is the subject;        -   else the lead noun is the last noun found in np;        -   else the lead np is the first np found in clause.    -   For an Object, the object is the direct object of the verb.    -   For a recipient, the recipient is the indirect object of the        verb

Specific rules may be provided to handle multiple clauses, interpretedaccording to their connective pattern: sequential clauses, prepositionalclauses, relative clauses, introducing complementary events into thetimeline, and subordinate clauses, flattened when introduced by verbs of“thinking” or “saying”.

At 460, the case frame is selected based on the first order matchingperformed at 420, the data stored in the case frame at 470 (in, forexample, data store 280). If no good match exists at 420, the case rulesare sorted, and if an intermediate binding exists at 425, theintermediate bindings are stored at 450 in a data structure stack toallow backtracking and optimization of the event interpreter 212. Anyremaining list of input tokens is carried across sequential terms as themethod loops back to 410, where mapping continues looping from 480 to410 for all tokens and POS until all tokens and POS patterns arecompleted.

Again returning to FIG. 3, at 360, event mappings are built from caseframe mappings. Mapped event data is stored in an event record (having aformat similar to that of FIGS. 11-18) for later use interpreting thenarrative data in the context of a story in accordance with thedescription below. A stored event frame including data elements fromnarrative data created in accordance with the foregoing comprises anevent record.

A method for mapping case frames to events is discussed below withrespect to FIG. 5. FIG. 5 illustrates one method for performing step 360in FIG. 3. At 510, for each mapped case frame, at 520 an attempt is madeto map the case frame (with some potential modifications) into an eventframe. There are five event frames for the five core semiotic functionmodels: PRP (Property attribution by copula), DO, TRANSFORM, TRANSFER,and TRANSACT. Each event model defines the mapping between case andevent. The elements of the event model include: agent; function;recipient; circumstances (such as time, location, instrument, and thelike); shades (such as manner and tone); and excerpt. For example, anevent frame may take the form:

Event_id Cast    Actor       Agent    Actor       Agent Narrative   Function Circumstances: time, location, instrument, etc. Shades:manner, tone, etc. Excerpt

If a match between a case frame and an event frame occurs at 530, then amapping occurs at 540 and an event record is stored at 550. If no matchoccurs at 530, then the method continues until a mapping between a caseframe and event frame occurs.

Property (PRP) attribution by copula applies to clauses (or case frames)which have a subject, verb, and complement, and where, in general, acomplement comprises a property relative to the subject. Hence, theattribution is the description provided by the adjective of the subject.A PRP mapping defines properties acquired by the target through PRPattribution, beneficial or detrimental.

In one embodiment, DO and TRANSFORM functions (i.e. MAKE functions) maybe skipped at succeeding levels of interpretation. In other words,detection of a DO or TRANSFORM verb is stored, but not used in analysisin a story mapping analysis. Most MAKE functions are descriptive ofoccurrences in sentence data. However, some MAKE functions may beimportant to a realization of a TRANSACTION or a TRANSFER. When a MAKEfunction is unrelated to any TRANSACTION or TRANSFER event, it may alsodiscarded. However, the technology categorizes and stores DO andTRANSFORM functions as they may be utilized in other analysisembodiments of the technology.

TRANSFER functions are most frequently found in a story narrative andimply asymmetrical transfer, such as abuse, mischief, and deceit. ForTRANSFER functions, the cast of actors involved is mapped to fit thesemiotic square value of the TRANSFER function. For example, the agentof a detrimental transfer like “abuse” is one of a “villain” or“trickster”. The recipient of a detrimental transfer like “abuse” is the“victim.”

TRANSACTION functions define a symmetrical event, typically found in theclimax event. Examples of a symmetrical event denote symmetry betweenthe actors, such as a conspiracy or affiance. The cast of actorsinvolved is adjusted to fit the semiotic square value of the function.In addition, co-agents of a symmetrical transaction like “conspiracy”may be included.

Once events are mapped and stored in event frames, the result of step360 is a plurality of event records for each item or set of narrativedata. The event records may be manipulated in a variety of ways. In oneembodiment, events are mapped to a narrative context by the storyinterpreter, and can be manipulated to produce one of several types ofstory analyses as indicated at 370 in FIG. 3.

FIG. 25A illustrates a summary of a television program with emphasis ona sentence whose structure is exemplified in the data structures shownherein. The summary illustrated in FIG. 25A may be a computer generatedsummary or a human created, narrative data input. Presently, a populartelevision program is the reality television program “Real Housewives ofOrange County.” The show has a number of characters and FIG. 25Arepresents a summary of a portion of one episode. Emphasis is placed onthe sentence “Lauri's troubles continue to mount” which will be used asan illustration in the following figures as to how a sentence isincorporated into an even data structure and thereafter used by thepresent technology.

FIG. 25B illustrates a data structure encapsulating the summary of FIG.25A. As shown therein, the summary of FIG. 25A is provided with a numberof sentences reflecting different events which take place in thetelevision narrative. For purposes of example, the succeeding figuresshow break-down and storage of the text “Lauri's troubles continue tomount.” The data structure. FIG. 25B includes a document ID, unique tothe particular document, and the specific text, in this case a sentence,which is analyzed in the data structures of FIGS. 26 and 27. FIGS. 25B,26, and 27 can represent a single data structure utilized to store allthe parts of speech and tokens for the sentence “Lauri's troublescontinue to mount” within the context of the summary illustrated in FIG.25A.

FIG. 26 illustrates a first portion of a data structure utilized inaccordance with the teachings herein to store an event based on thesentence “Lauri's troubles continue to mount.” As illustrated therein,each event has a specific unique identifier (OBJECTID) and may includedata associating the event with a particular season (SEASON ID) andprotagonist (in this example, “Lauri Waring Peterson”, a character onthe show). Also included is data on the “series” and “year.” The eventis broken down into a “type: noun phrase” for “Lauri Waring Peterson”and further broken downs into specific identifiers for each word in thephrase. Functions are identified and stored. In this case, the terms“mount” and “continue” are identified as DO functions. Notably thissentence is descriptive in nature and does not include any TRANSACTIONor TRANSFORM functions—no action happens in the sentence.

FIG. 26, the elements of the sentence are classified according to theirusage and the functional ontology. For example, the token “Lauri” is anoun phrase classified as possessive (NPO), Lauri is the first name of agirl (FNG), is a member of the cast (CST), and is also a plural propernoun (NNP).

FIG. 27 illustrates a second portion of the data structure used to storethe event a data highlighted in FIG. 25A. FIG. 27 illustrates astructure similar to FIG. 26, except that it in this structure, theindividual tokens and identifying characteristics thereof are stored,whereas in FIG. 26, more contextual information is stored. Individualcharacteristics of each token is stored in this data structure whichallows for additional types of manipulation of the data in the inputnarrative. It should be noted that the data structures of FIGS. 25B, 26and 27 may all be linked as a single structure.

FIG. 28 illustrates the data structure of FIG. 25B used to store adifferent sentence and different summary. This summary is from adifferent episode of the same television show and states: “Jo getsdumped by her boyfriend Slade. Lauri gets a ring. Lauri's son Josh movesinto the town house next season but “breaks house rules” and is kickedout and then moved into Lauri's new husband's ex-wife's house.” Anydifferent number of summaries may be stored in the data structure andcombined together to create a season summary narrative of the show. InFIG. 28, the sentence “Lauri gets a ring” is emphasized. However, itshould be noted that in the actual data structure, the sentence isplaintext.

FIG. 29 illustrates a first portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 28. FIG. 29 illustrates the data structure used tostore the sentence “Lauri gets a ring” from the summary of FIG. 28. Thedata structure. FIG. 29 is similar to that of FIG. 26. It should benoted that in FIG. 29, a different, unique object ID, different seasonID, different year, and a different event ID are all illustrated. Theprotagonist in this instance is the same—Lauri Waring Peterson—and thedata structure thereafter identifies each of the particular tokens inthe sentence and classifies them according to their functional nature inthe functional ontology. In the context of FIG. 29, the term “get” isclassified as a copula and hence represents the transition of propertyattribution (the ring) to Lauri.

FIG. 30 illustrates a second portion of a data structure utilized inaccordance with the teachings herein to store a characterization of thesentence of FIG. 28. As a FIG. 27, FIG. 30 is a more token-centricbreakdown of the data illustrated in FIG. 29.

FIG. 6 illustrates one method for performing step 370 in FIG. 3 tomanipulate event records into story analyses by first mapping stories.Again, it should be understood that other analyses of the narrativeinput data may be performed at step 370 and FIG. 6 illustrates only onetype of analysis using the story interpreter 214. At 605, for each eventidentified by EVENTID, an attempt is made to map the event to astory-based on a story pattern. At 610, each story pattern is retrievedwhere a story pattern is defined as a narrative and cast/credits. At620, for each story rule, an attempt is made to match the event to thestory pattern, again by first order matching. If there is no patternmatch, a determination as to whether an intermediate binding exists at652 is made and if so the intermediate binding is stored at 655. Once amatch is made at 650, a further determination is made at 655 as towhether a pre-existing story mapping exists or whether this is a newstory. In either event, the event ID is mapped to the new or existingstory pattern at 660. An exemplary story pattern may take the form:

Timeline    [Event_id, Event_id ...] Narrative    Name    List ofeventful functions  Cast    List of eventful actors

When performing a story analysis, from event to story, a storyinterpreter 214 may operate to reorder a textual sequence into a set ofthreads inside the same narrative. The story rules 240 provideheuristics to identify and reorder the threads an exemplary story ruledefined as follows: [(“villain punished”, [(villain, abuse, victim),(victim, ask for help), (hero, contract, victim), (hero, punish,villain)].

The system may include thousands of story rules based on implicit storypatterns defined for the story interpreter 214. As noted above, eachstory comprises a narrative and a cast. Each narrative includes patternof events (“love story”, “natural disaster”) and has a narrativestructure: sequences, parallel sequences, and cycles. As noted above,each event in a story comprises a function, actors, circumstances, andshades. TRANS functions serve as the basis for story analysis. Actorsmay be characterized in terms of their role within the story, such as,for example, a protagonist, an ally, a villain, a witness, a victim, orthe like. Circumstances define, for example, time, location, andsettings. Time is important to events as it is used to generate atimeline of events in one of the one of the analysis outputs discussedbelow. Shades add a descriptive nature to each of the events. Storiesmay also include sub-stories, or sub-plots, collectively referred to asepisodes. Each episode comprises a sub pattern of events inside the mainnarrative. Some subplots are classified as disruptive, where, forexample, they may comprise a “red herring” to the story.

At step 650, the story interpreter matches cast and events to storypatterns. A story pattern is a sequence of events associated to athematic name. FIG. 22 illustrates a narrative genre taxonomy whichreflects themes which may constitute names of individual stories. Forexample, one theme is a “rags to riches” story. Each event associatesfunction and a cast of actors. As in the event interpreter, some eventsare optional. Story rules are sorted and the method follows the samezero order logic as the event interpreter. The story rules leverage theconnective patterns identified by the event interpreter, and bindings ofindividual event IDs are returned. Eventful bindings are returned to thedata store 280.

Some events and roles will be generated as probable by entailment rules.For example, the existence of a cadaver implies that there is a killingand some actor is a killer. In creating story timelines, the“protagonist” that is the focus of each thread in a story can be used totrace and to chain events across a timeline, as illustrated in FIGS. 31and 32.

Stories have often two threads for the two lead protagonists, each ofthem mirroring the other using opposite semiotic square values. Theshift of focus on the mirroring thread is often the result of a swap ofroles: e.g. the agent becoming the recipient. After each function, eachcharacter in cast updates his/her “balance sheet” according to thebalance of all deeds and retributions [00140] If the story patternsmatch, then the event ID fields are matched to the story pattern fields,at 660. If not, the method continues at 650 until the story pattern ismatched.

The result of the foregoing process is to provide a sequence of storyevents which in one embodiment may comprise a machine generated story,created from multiple sets of narrative data taken as input. The methodmay be repeated for any new set of narrative data, thereby allowingdynamic updating of a machine generated story for each new set ofnarrative data taken as input to the method.

As noted above, each set of events can be utilized to create differenttypes of outputs. FIGS. 31 and 32 represent data structures which can beutilized to create and store timelines.

FIG. 31 illustrates a data structure referencing event data structuresand which may be used in the creation of a time line. In FIG. 31, eachevent, in this case, the events discussed above with respect to FIGS.25B through 30 are illustrated in the data structure. It will beunderstood that every sentence in every summary has a similar datastructure to that identified in FIGS. 31 and 32 if it is present in atimeline. As illustrated in FIG. 31, for each protagonist, a series ofevent IDs associated with that protagonist, along with the text of eachparticular event, and its associated document ID parent (the summarywhere it resides) is stored in the data structure. Only a portion of theevents for protagonist Lauri Waring Peterson are illustrated in FIG. 31.It will be understood that there are any number of events that can beassociated with this particular protagonist.

FIG. 32 illustrates a partial data structure storing an event time linefor a given character protagonist in a story. The data structure of FIG.32 illustrates the individual timeline of events for a particularprotagonist, in this case protagonist “Vicki” who is another characteron the show. Each timeline is a series of events, with each eventorganized by year, season ID, document ID, episode ID, event ID, and thespecific text which is associated with the particular event. The outputof a timeline, data structures, such as that shown in FIG. 32 is asequential, text-based timeline structure which can be output to adisplay or other document output for consumption by a user. The datastructure. FIG. 32 is constructed by the analysis engine 250 discussedabove with respect to FIG. 2.

FIG. 33 illustrates a data structure storing data utilized tocharacterize a protagonist in the context of the technology. Eachprotagonist in the story can be represented in terms of the datastructure for use by the computational engine herein. In the datastructure of FIG. 33, the protagonist Lou Knickerbocker ischaracterized. Lou Knickerbocker is an ex-husband of another character“Tammy” and is identified with a particular object ID, related to aparticular show (“series”), and additional information, such as an imageof the character, can be stored in the data structure. It will beunderstood that a data structure similar to that shown in FIG. 33 can bepresent for every protagonist sought to be tracked in the context of thepresent technology.

In another unique aspect of the technology, story rules may bepredicated on narrative balance, and in particular narrative balancewith respect to each actor in a story. FIG. 20 illustrates the conceptof narrative balance with respect to actors. In FIG. 20, two actors,actor A and actor be represented as performing respective wrongdoing andretribution actions. If actor A commits wrongdoing against actor B,actor be will likely perform a retribution action against actor A. Thisbalance between transgression and retribution occurs throughout athematic structure of the story, and can be analyzed relative to eachactor in the story.

Two forms of balance found in any narrative are transgression andretribution. If there is a transgression, there will also be aretribution. Between the two negative forms of prohibition andviolation, the second one is clearly the most decisive. Any contractwill be violated, and any rule will be transgressed. The onlycounterweight to transgression will be the result of thymic functions,and/or adjustments of degrees of axiological opposition between moralstandards.

The semiotic square of functions helps to expand the analysis of thefunction by exploring opposite, reciprocal and gradual relationships.Typically a retribution can then be chained with the start of a negativetransaction: if A attacks B, then the reciprocal expected event is aretribution by B towards A. (FIG. 20) These two sides of the samepattern might be triggered at different times of the same scenario, orbe even triggered in different mission or scenario contexts.

Each actor triggers his plan according to his own point of view. In awrongdoing/retribution pattern, the act object of retribution has onlyto be considered to be an incitement to a new wrongdoing to obtain anarrative cycle. The two associated sequences then correspond to twocomplementary points of view of the same action: i.e. redress for theaggressor and wrongdoing for the victim, alternately attributed to thetwo protagonists, with the wrongdoing becoming a damage to be redressed.

The dynamics of the archetypal narrative works around a doubleinversion. This canonical sequence chains three phases: opening, core,and closing. The opening of a sequence involves preparation of aresource which is the object that will receive the sequence core, or theobject of the sender controlling the sequence. The core of the sequenceinvolves the execution of events and transformations that justify theoverall significance given to the sequence (potentially reflected in thename of the sequence). The closing of the sequence which may be actualor virtual, restores the initial state of balance freeze the resourcesused in the opening of the sequence, replaces protagonists in theenvironment.

An example of an axiological ontology adding another layer of complexityto the contractual square is the articulation of secret and illusion,stemming from a difference of degree between two levels of (recognitionof) reality. Access to the ontology of this technology allows one todistort the terms of the contract: keeps the terms secret, lie about theterms, give false commitments, etc. These distortions will be repaidlater in the narrative, unmasking the real intents of the protagonistsand leading to subsequent plot twists. Thymic and axiological overlayson contractual transactions carry aspectual (occurrence, duration,frequency) and intensity values, both varying over time andcircumstances. Again, these inflections will generate emotional shiftsand lead to new developments. An axiological ontology can be reflectedin the semiotic square such as that illustrated in FIG. 21.

At 380, based on the events mapping, functional mapping, and narrativemapping, an analysis of the story may be created and directed to output260. In the above, any of a number of different types of outputs 260 canconsume the analysis of the story. As noted above, analysis engine 250may provide a number of analyses to any number of outputs. The analysesinclude, but are not limited to: generating a timeline of events for adisplay and/or consumption by a story-based social network; generating aprediction of a next event in a timeline; generating a believabilityscore and generating a comparison of a story to other stories.

FIG. 7 illustrates one method for performing at timeline analysis at370. In FIG. 7, the analysis is to build a timeline of events. Atimeline of events may be output to a display device or to anothercomputing environment which consumes the timeline for various purposes.One such computing environment is described below with respect to astory-based social network.

As noted above, each record of an event includes an EVENTID andcircumstances including time, and location. Events have been mapped tostory rules, allowing classification of the stories as a series ofevents. At 710, for each event in a story relative to a story mapping,the event is ordered relative to time in an ordered list. As notedabove, protagonists can be utilized to map story threads through thestory timeline. At 720, a selection of two or more events may be made.Because stories may have a significant number of events, a timeline maybe programmatically limited to a specified number of events, theimportance of which can be calculated based on the relative importanceof the function, the actor and the objects involved. At 750, adetermination is made as to whether any one event is relative to apre-existing timeline or whether this event is related to a newtimeline. If the event is not relevant to a pre-existing timeline then anew event is added to a new timeline at 795. If the sequence can berelated to a particular pre-existing story, then a determination is madeas to whether not the new event supersedes the previous event at 760. Ifthe event does not supersede a previous event, then the event is addedto the timeline at 790. If event does supersede the previous event, thenat 780 the previous event is removed from the previous timeline, and thenew event added to the previous timeline at 790. If neither 750 nor 760are true, the event is added to the timeline and the next event isretrieved at 710.

Another type of analysis that may be performed at 370 is story eventprediction.

FIG. 8 illustrates one analysis for predicting one or more next events.As used herein, a next event in a narrative may be referred to as apredictive event. Prediction of events may occur using one of a numberof different methods. Various alternatives exist for utilizing thedifferent methods. In one embodiment, a single method is used forprediction. In an alternative embodiment, multiple methods are used forprediction, and a selection of the prediction is based on one or moreweighting factors relative to the method utilized.

A first predictive method includes analysis of event sequences using astatistical method, such as a Markov chain of events. Within a narrativecontext, the Markov chain analyzes a sequence of random variables (inthis case events) with a property defining a serial dependence onlybetween adjacent portions of the chain. As stories generally follow achain of linked events, Markov analysis can be applied at the eventlevel (using the semiotic square of elements in the event frame) todetermine a predictable next event in a sequence, in this case a story.

A second prediction method is based on narrative balance. The constantnarrative balance has been discussed above. For any story, and for anyprotagonist (in this case the subject of the prediction), a narrativebalance analysis evaluates the number of transgressions and retaliationsin a given story chain at a given point in the story. Transgressions andretaliations can be determined by, for example, mapping for each TRANSverb an indication of whether the verb identifies an action associatedwith a transgression or retaliation and identifying event mappings whichindicate transgression and retaliation events on a per protagonistbasis. Next one determines whether or not the number of transgressionevents is greater than the number of retaliation events for a givenprotagonist. If the number of transgression events is greater than thenumber of retaliation events for a given protagonist, the protagonist islikely the subject of a retaliation event.

This characterization is performed for each protagonist such that thereare no “villains” and “heroes”—there are only actors. If oneprotagonist/actor, on balance, has more transgressions than retaliationsrelative to another actor, one can predict what the next action relativeto each actor will be based on narrative balance. The actor with moretransgressions is likely to retaliate against the actor who hascommitted the transgressions against him/her.

Narrative balance prediction can be further enhanced by seeking shiftprecursors: protagonists with a negative prequel will looking forward tohaving positive sequel. This extends the narrative balance predictionmethodology to overall story analysis.

Another method for prediction of a next event is to examine protagonistbehavioral patterns, learned from similar situations. For any givenprotagonist in a story, all events involving a given protagonist can beevaluated and examined for semiotic similarities. If an event in a storyindicates that an actor will kill when being chased by another actor, asimilarity analysis will equate a likelihood of a next action to predictthat the same actor will likely kill when being pursued by a differentactor, or even that the act of killing can be extended to other elementsof the semiotic square defined for the element of “chase.”

Returning FIG. 8, at 810, one of the above methods of prediction may beselected. At 830, for each predictive method, a prediction and apredictive weight is generated. The predictive weight is an associationof a value with one or more next events resulting from the predictionmethod used at step 810. For a given event which results from aprediction method, the weight associated with it may be relative to thelikelihood the given prediction method attributes to the next eventoccurrence. Predictive weights can be adjusted by selecting, for anygiven method, arbitrary values comprising programmer selectedassignments for preferences based on the method, or can beprogrammatically calculated based on past accuracy of the predictivemethod utilized. For example, one may assign greater weights toprotagonist's behavioral patterns than to statistical analyses.

At 850 a determination is made as to whether or not another methodshould be utilized to create a prediction. In one embodiment, step 850may be skipped and only one predictive method will be utilized. Inanother embodiment, all methods can be utilized. The determination 850may be a programmatic selection configured into the computingenvironment 200. Once one or more predictions have been made, thisprediction is selected at 860.

In another embodiment, each of a number of predictive methods may beperformed to provide at least as many predictive events as availablemethods and may further include performing semiotic substitution on oneor more events in the story to produce additional predictive eventsbased on each of the aforementioned methods. In a further embodiment,all such predictions in the form of predictive events are returned tothe output.

FIGS. 34 and 35 illustrate example of a data structures utilized inprogrammatic clustering. Generally, clustering may be performed bydetermining a frequency of occurrence of each word, POS and tokenpresent in a narrative, and grouping associations between terms based onhigh frequency occurrences of certain terms. Clustering can also be usedas a measurement of probability of an association between two eventswhich in turn can be used in the context of prediction and in generatinga believability score. In FIG. 34, a first portion 3410 of the datastructure maintains a listing of each term, POS and function and thefrequency of occurrence thereof in a story. A second portion 3420maintains a characterization of each word, function or POS by itsassociation to the semiotic ontology. Once frequent terms areidentified, a threshold frequency may be applied to remove less frequentterms from analysis, and thereafter links between frequent termsidentified based on clusters or groupings of the most frequent terms ina narrative.

In the example of FIG. 34, “disentitle” appears as a TRANSFER orTRANSACTION function six (6) times. (Recall that in certain types ofanalyses, DO and MAKE functions—also shown in the example of FIG. 34 at3420—are ignored in this story analysis.) Any of a number of clusteringalgorithms may be used. In the vector-space model, a text document maybe represented by a vector of frequencies of the terms therein.Clustering may be based on the functional ontology, on characters,locations or any classification of terms.

Clustering generally groups a set of objects in such a way that objectsin the same group are more similar to each other than to those in othergroups. Clustering may be performed by any number of differentalgorithms. In the present technology, connectivity based clustering maybe utilized to determine relationships between events based on adistance measure between the events when organized into a cluster. Anynumber of different algorithms connect events to form “clusters” basedon their distance. At different distances, different clusters will form,which can be represented as a hierarchy of clusters that merge with eachother at certain distances. [00168] Connectivity based clustering—basedon distance—can be used to generate, for any event, a believabilityscore. The believability score can be created based on the relativedistance between two events in a cluster, with one of the eventsconstituting a prototype (cluster center) from which the believabilityscore is measured. The believability score can be added to anypredictive analysis as part of an output (timeline or story) to reflecta level of confidence (or believability) in the projection.

For predictability analysis, clustering distances can be used afterfiltering for threshold distances. Event clusters can be defined asareas of higher density than the remainder of the data set. Objects inthese sparse areas—that are required to separate clusters—are usuallyconsidered to be noise and border points.

Thus, only events at points within certain distance thresholds ordensities may be considered where such events satisfy a densitycriterion defined as a minimum number of other events within a givencluster radius.

FIG. 9 is a flowchart illustrating another type of analysis which may beperformed once the events have been mapped to a narrative analysis. FIG.9 is that of detecting similarities between stories which have beenmapped to story rules. Although stories may contain different eventframes, actors, and circumstances, similarities between the respectivestories can be understood based on an extension of the semiotic squareanalysis.

In FIG. 9, one or more of at least three similarity analyses may be usedto detect similarity between two stories. In a first aspect, a taxonomicdistance between actors, narratives, or both may be calculated at 910.In a second aspect, optimal matching between events may be calculate at920. In a third aspect, semiotic matching between events in respectivestories may be used at 930. One or more of the resulting similaritycalculations may then be selected at 940 based on the application forwhich the similarity calculation is used.

At 910, predicting story similarity may be based on abstracting thestory structure based on the aforementioned story rules, and for eachelement in the story rule, determining taxonomical distance between thatelement and another element a respective taxonomy. Two stories may beconsidered similar if their narratives and/or cast are similar.Narrative similarity may be a combination of: distance in narrativestaxonomy and optimal matching between events in narratives. Castsimilarity is a function of a distance in an actors taxonomy.

A number of different taxonomies may be provided to classify differenttypes of topics in a story. FIG. 22 shows a topics taxonomy which may beutilized by the technology to classify topics of stories into arelationship. Other types of taxonomies utilized by the technologyinclude, for example, a settings taxonomy, and actor taxonomy(illustrated with respect to FIG. 23), and a taxonomy of narrativegenres (FIG. 22). Taxonomies are used to classify and specifyrelationships between each of the various subjects of the taxonomies.Illustrated herein are the narrative genre taxonomy (FIG. 22) and theactors taxonomy (FIG. 23). However it is to be understood that anynumber of different taxonomies may be utilized in accordance with thepresent technology. The particular relationships in the taxonomy may beprogrammed into one or more data structures having a form similar tothat shown in FIGS. 11 through 18.

To compute similarities between a given narrative and other narratives,in a first embodiment, a linear distance between the respective elementsin a narrative to other elements in the narrative being comparedthereto. In one embodiment, this may be the linear calculation of adistance between two elements in a given taxonomy. For example, if astory has been classified as a destiny genre (illustrated in FIG. 22)and specifically a “big break” genre, and another story is classified asa destiny genre and a “rags to riches” story, each of these two items inthe destiny genre can be said to be related by a linear distance of 1.However the linear distance from a “family” theme of “breakups anddivorces” the “big break” genre would be much greater e.g. a lineardistance of four nodes.

A second methodology which may be used alone or in combination with thelinear distance calculation is that of an optimal matching at 920.Optimal matching attempts to provide, for each of the elements in thenarrative, a determination of the relationship to a correspondingelement and another narrative. Optimal matching is a sequence analysismethod to assess the dissimilarity of ordered arrays of tokens (herein,events,) that usually represent a time-ordered sequence of states. Oncesuch distances have been calculated for a set of observations (e.g.individuals in a cohort) classical tools (such as cluster analysis) canbe used. OMA is a family of procedures that takes into account the fullcomplexity of sequence data. The objective is to identify a typology ofsequences empirically. The core of OMA is a two-step procedure. First,given a set of sequences, find the distance between every pair ofsequences though an iterative minimization procedure. This will give adistance matrix for all the sequences. Secondly, apply clustering orcognate procedures to the distance matrix to ascertain if the sequencesfall into distinct types. The objective of this first step is to find,for each pair of sequences in the sample, the lowest ‘costs’ needed toturn one sequence into another, using three elementary operations:insertion, deletion, and substitution—such as substitution using thesemiotic square defined herein.

Utilizing the ontology discussed herein, as well as the semiotic squareof each element in a narrative, one can compute the number of similarelements, narrative by narrative, and determine an optimal matchingvalue for each event. Optimal matching between two different narrativescan produced an optimal matching value score, and the score may becompared with the taxonomical value distance, or combined with thetaxonomic value distance, to achieve a similarity score between twodifferent narratives. Multiple narratives can be compared and rankedbased on this similarity score. In another aspect, if a user promotes aparticular story as being similar to another story, this can be factoredinto the similarity index.

At various points in the aforementioned disclosure, discussion of usingthe semiotic square substitution has been described. FIG. 10 is aflowchart illustrating a computer implemented process for implementing asemiotic square substitution for any of the aforementioned processes ofsubstitutional analysis.

Semiotic square substitution at 930 for each of a number of moments in anarrative can be utilized at multiple levels in the context of thepresent technology. FIG. 10 illustrates a method for performing semioticsquare substitution and evaluation of, for example, case frames. Foreach event at 1010, and for a selected number of events, at least one ofthe elements within the particular case frame (function, actor, shape,or object) may be evaluated relative to a semiotic square. At 1030, thesemiotic square for the particular element (the word associated withparticular function, actor, shape, or object) is returned, and for eachvalue for each word in the square at 1050, (or for a subset of elementsin square,) square values for each element under evaluation may besubstituted (at 1060) into the case frame to generate a new event at1070. The new event can then later be used to perform any of theevaluations discussed herein. For example, substituting a SPNA value foran SPA value will result in oppositional element in a particular story.The same event can then be passed through the story mapping, timelineanalysis, prediction analysis, or similarity analysis to determine aresult based on the substituted value. For example, instead of a herobeing victorious, a villain can be victorious. The substitution willimpact the similarity or dissimilarity determination for a particularnarrative. The substitution may be repeated at 1060 each word in thesemiotic square, and any of the values in the case frame.

Any one or more of the above methods 910, 920, 930 may be used and adetermination made at 940 to select the similarity result of thecalculation.

FIG. 24 is an illustration of a computing system environment suitablefor providing a story-based social network in accordance with thepresent technology.

FIG. 24 illustrates a computing environment which may be implemented asan output 260 for the computing environment of FIG. 2. The computingenvironment comprises a social network computing environment 2410. Thesocial network computing environment 2410 may include therein aprocessing computing environment 200 a which will be understood to besimilar to computing environment 200, including all the elementsthereof. For purposes of brevity, only the analysis engine portion ofcomputing environment 200 is illustrated as analysis engine 2415.Analysis engine 2415 may operate to perform any of the analysesdiscussed herein. Social network computing environment 2410 can includeone or more processing environments 200 a.

Social network computing environment 2410 includes a friend database2420, application server 2435 and one or more analysis engines 2415.Each analysis engine includes a story processor creating a curated storyin accordance with the description herein. The story processor takes asinput sets of narrative data 2405 which comprises text inputs which areprovided to the story generator. In addition, other data sources 2432can provide data to the analysis engine and story processor. Other datasources may include, for example, social networks such as Twitter andFacebook, weblogs or “blogs”, commercial new sources such as CNN andMSNBC, or any electronically available narrative data source which maybe accessed directly or indirectly using programmatic means. In afurther embodiment, the sets of narrative data 2405 may beuser-selected. In one embodiment, an interface presenting a set ofnarrative data encompassing a variety of different input stories (suchas news articles) is provided to a user of social network computingenvironment 2410 via user device 2450. The computing environment 2410receives a user-selection of one or more input stories as input sets ofnarrative data 2405, and the analysis is performed based on theuser-selected set of input data.

One or more client devices 2425 may be coupled to the social networkcomputing device 2410 via one or more public or private networks, suchas the Internet. Likewise, a user device 2450 may also be coupled to thesocial network computing environment 2410 via one or more public andprivate networks. Each user device 2450 and client device 2425 may be aseparate processing device, or may be considered an applicationexecuting on a processing device which provides access to the output ofthe social network computing environment 2410. An example of such anapplication would be a rub browser, or application server 2435 outputs awebpage to the client device 2425 or user device 2450.

As illustrated in FIG. 24, analysis engine 2415 creates, within a storyprocessor 2430, a social story 2475. Social story 2475 may be acombination of a narrative timeline for a news or current event, or apopular television narrative, which includes excerpts from the narrativedata, all of which map to a particular story in accordance with theteachings herein. The story processor can be configured to receive userinput 2455 provided by the user device 2450. For any given story, andany user of the social network, the social story may be provided to auser device 2450. Upon review of the social story at the user device2450, a user may select friends from the friend database 2420 with whomto share and discuss the social story. A friend database 2420 allows auser to control which users friends will be connected to a social story,the social story thus being output to those users in a socialrelationship with each other. A user may provide user modification tothe social story prior to sharing the social story with user's friends.Once social story including user modifications is provided to clientdevices 2425, users of the client devices may provide their own useredits to the social story. The result is a social story 2475 with userinput 2455, and various elements of friend input 2462, 2464, and 2466.The resulting user and friend modified social story is then output toall devices 2450 and 2425, enabling users to interact with the usersocial story in the social network computing environment 2410. Thisprocess can be repeated and updated for each element of friend input anduser input to the social story.

As illustrated on user device 2450, a user device may include usermodifications, an event timeline, and friend input is furtherillustrated in FIG. 24, multiple curate stories may be created by thestory processor 2430 and any number of social stories access by userdevice 2450 client devices 2425. User device 2450 may comprise apersonal computer, mobile computer, mobile phone, tablet, or othersuitable processing device. Application server 2345 may be a webapplication server adapted to deliver elements of the social story anduser input to user device 2450 as client devices 2425, or may providededicated applications and accompanying data to user device 2450.

FIG. 36 is an illustration of an exemplary computing system suitable forimplementing in the computing systems discussed herein. As illustratedin FIG. 36, the computing system 3702 includes a processor 3710. Aprocessor 3710 for computing system 3702 is configured to executesoftware instructions in order to perform functions as described in thevarious embodiments herein. A processor 3710 for a computing system 3702may be a general purpose processor or may be part of an applicationspecific integrated circuit (ASIC). A processor 3710 for a computingsystem 3702 may also be a microprocessor, a microcomputer, a processorchip, a controller, a microcontroller, a digital signal processor (DSP),a state machine, or a programmable logic device. A processor 3710 for acomputing system 3702 may also be a logical circuit, including aprogrammable gate array (PGA) such as a field programmable gate array(FPGA), or another type of circuit that includes discrete gate and/ortransistor logic. A processor 3710 for a computing system 3702 may be acentral processing unit (CPU), a graphics processing unit (GPU), orboth. Additionally, any processor described herein may include multipleprocessors, parallel processors, or both. Multiple processors may beincluded in, or coupled to, a single device or multiple devices.

Moreover, the computing system 3702 includes a RAM 3720 and anon-volatile storage 3730 that can communicate with each, and processor3710, other via a bus 3708. Illustrated in the non-volatile storage 3730are components including a parser, analysis engine, event interpreterand story interpreter as discussed herein.

As shown, the computing system 3702 may further include a display unit3750, such as a liquid crystal display (LCD), an organic light emittingdiode (OLED), a flat panel display, a solid state display, or a cathoderay tube (CRT). Additionally, the imaging processor may include an inputdevice 3760, such as a keyboard/virtual keyboard or touch-sensitiveinput screen or speech input with speech recognition, and which mayinclude a cursor control device, such as a mouse or touch-sensitiveinput screen or pad. A network interface 3740 may be a wired or wirelessnetwork interface allowing the system 3702 to communicate with otherdevices in the manner discussed herein, via public, private, wirelessand wired networks.

In the embodiment illustrated in FIG. 36, the data store is illustratedin FIG. 2 are shown, as well as elements comprising code stored innonvolatile storage, which may be executed by the processor 3710 tocreate a parser 205 a. An analysis engine 250 a, event interpreter 212a, and the story interpreter 214 a, such code when implemented by theprocessor 3710 creating the parser 205, analysis engine 250, eventinterpreter 212, and story interpreter 214.

Memories described herein are tangible storage mediums that can storedata and executable instructions, and are non-transitory during the timeinstructions are stored therein. A memory described herein is an articleof manufacture and/or machine component. Memories will described hereinare computer-readable mediums from which data and executableinstructions can be read by a computer. Memories as described herein maybe random access memory (RAM), read only memory (ROM), flash memory,electrically programmable read only memory (EPROM), electricallyerasable programmable read-only memory (EEPROM), registers, a hard disk,a removable disk, tape, compact disk read only memory (CD-ROM), digitalversatile disk (DVD), floppy disk, Blu-ray disk, or any other form ofstorage medium known in the art. Memories may be volatile ornon-volatile, secure and/or encrypted, unsecure and/or unencrypted.

Aspects of the present disclosure are described herein with reference toflowchart illustrations and/or block diagrams of methods, apparatuses(systems) and computer program products according to embodiments of thedisclosure. It will be understood that each block of the flowchartillustrations and/or block diagrams, and combinations of blocks in theflowchart illustrations and/or block diagrams, can be implemented bycomputer program instructions. These computer program instructions maybe provided to a processor of a general purpose computer, specialpurpose computer, or other programmable data processing apparatus toproduce a machine, such that the instructions, which execute via theprocessor of the computer or other programmable instruction executionapparatus, create a mechanism for implementing the functions/actsspecified in the flowchart and/or block diagram block or blocks.

These computer program instructions may also be stored in a computerreadable medium that when executed can direct a computer, otherprogrammable data processing apparatus, or other devices to function ina particular manner, such that the instructions when stored in thecomputer readable medium produce an article of manufacture includinginstructions which when executed, cause a computer to implement thefunction/act specified in the flowchart and/or block diagram block orblocks. The computer program instructions may also be loaded onto acomputer, other programmable instruction execution apparatus, or otherdevices to cause a series of operational steps to be performed on thecomputer, other programmable apparatuses or other devices to produce acomputer implemented process such that the instructions which execute onthe computer or other programmable apparatus provide processes forimplementing the functions/acts specified in the flowchart and/or blockdiagram block or blocks.

Although the subject matter has been described in language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims.

What is claimed is:
 1. A machine implemented method, comprising;accessing narrative data, the narrative data comprising a plurality ofsequence of words, each sequence of word including a verb and arrangedin a sentence pattern; reading a semiotic square function data table foreach verb in the sequence of words, each semiotic square function datatable classifies at least one verb in each sentence pattern as afunctional type and includes one or more words in a semiotic squarerelationship to the verb classified, the functional type applying asymmetrical relationship between a first actor and a second actor in thenarrative data; parsing each sentence which includes a verb matching afunctional type to match sentence subjects and objects to an event ruleselected from a set of event rules; storing data from each subject andobject in a sentence as an event record; and displaying an analysis ofthe narrative data on a user perceptible device to a user based on asequence of event records.
 2. The machine implemented method of claim 1,wherein the semiotic square function data table includes a MAKE functiontype, a TRANSFORMATION type, a TRANSFER type, and a TRANSACTION type. 3.The machine implemented method of claim 2, wherein the analysis ignoresthe MAKE function type and TRANSFORMATION function type.
 4. The machineimplemented method of claim 1 further comprising generating a timelineof time-ordered event data.
 5. The machine implemented method of claim1, wherein displaying the analysis of the narrative data on a userperceptible device to a user further comprises displaying on a userperceptible device a sequence of events comprising a story narrativecomprising the sequence of event records.
 6. The machine implementedmethod of claim 1 further comprising reading a semiotic square subjectand object data table, swapping data in event records for subject andobjects in the semiotic square subject and object data table.
 7. Themachine implemented method of claim 1 wherein the parsing maps narrativedata to a case frame including: a subject, an object, circumstances,shades, and an excerpt, the parsing creates a case frame record for eachmapping.
 8. The machine implemented method of claim 7 wherein theparsing maps the case frame record to an event frame.
 9. The machineimplemented method of claim 8 wherein the semiotic square function datatable includes a DO type, a TRANSFORMATION type, a TRANSFER type, and aTRANSACTION type, each function type having a different event frametype.
 10. A computer implemented method of analyzing a story in text toproduce an output, comprising: parsing the text to produce a list ofwords, ones of the words comprising nouns and verbs, the parsingproducing a sentence structure; reading a function classification table,the function classification table storing ones of the verbs with adefinition of each verb as one of a DO function type, a TRANSFORMATIONtype, a TRANSFER type, and a TRANSACTION type; reading, for at leasteach verb, a semiotic square data table; accessing an event rulecontaining an association of a verb and functional classification to theevent record, the event record mapping events to an event frameconfigured based on a verb being classified as the DO type, theTRANSFORMATION type, the TRANSFER type, and the TRANSACTION type;generating event records including ones of the words from the sentencestructure; storing the event records; and displaying an analysis of theevents including at least an ordering of the events on a userperceptible device to a user.
 11. The computer implemented method ofclaim 10, wherein displaying the analysis further comprises displaying astory narrative comprising a sequence of event records.
 12. The computerimplemented method of claim 11 further comprising reading a semioticsquare subject and object data table and swapping data in event recordsfor subjects and objects from the semiotic square subject and objectdata table.
 13. The computer implemented method of claim 10, wherein theparsing maps narrative data to a case frame that includes a framecomprising: a subject, an object, circumstances, shades, and an excerptand the parsing creating a case frame record for each mapping.
 14. Thecomputer implemented method of claim 13 wherein the parsing maps caseframe records to event frames and the parsing ignores the Do type andthe TRANSFORMATION type.
 15. The computer implemented method of claim 14wherein the function classification data table includes the DO functiontype, the TRANSFORMATION type, the TRANSFER type, and the TRANSACTIONtype, each function type having a different event frame type.
 16. Acomputing system adapted to analyze narrative textual data, thecomputing system includes a processor and a storage medium, comprising:a data structure stored in the storage medium including a classificationtable, the classification table includes a plurality of verbs classifiedas functional types, at least one functional type characterizes arelationship between a first actor and a second actor in the narrativetextual data, the classification table includes at least one semioticsquare term for each of the plurality of verbs; the computer systemincluding the processor and the storage medium and a plurality of linesof code that is configured to: collect electronic textual narrative datadocuments; read a classification data structure, the data structureincludes classifications of verbs as functional types, theclassification data structure includes one or more words in a semioticsquare relationship to the verb classified, the classification datastructure includes classifications of at least one verb in each sentencepattern as a functional type, at least one functional type applying asymmetrical relationship between a first actor and a second actor in thenarrative data; parse each sentence which includes a verb matching afunctional type to match sentence subjects and objects to an event rulecontaining an association of a verb and functional type to an eventrecord; store data from each subject and object in a sentence as anevent record; analyze the narrative data relative to a common storytheme based on a sequence of event records and output an analysisresult; and display the analysis of the narrative data to a user using auser perceptible device.
 17. The computing system of claim 16 whereinthe computer system is further configured to generate a timeline oftime-ordered event data, receive textual data including a later event inthe sequence of events and update the timeline with the later event inthe time-ordered event data.
 18. The computing system of claim 17wherein the data structure includes functional types comprising at leasta DO function type, a TRANSFORMATION type, a TRANSFER type, and aTRANSACTION type.
 19. The computing system of claim 17 further includinga semiotic square data structure for subjects and objects in narrativedata documents and the computer system is further configured to swapdata in event records for subjects and objects from the semiotic squaredata table.
 20. The computing system of claim 16, wherein the computersystem is further configured to collect is configured to receive auser-selected set of textual narrative data document and analyze outputsa social story including a selected sequence of events to a selected setof processing devices based on a defined social relationship.